Use of RNase H and primer extension to analyze RNA splicing.

A new method for the characterization of pre-mRNA splicing products is presented. In this method RNA molecules are hybridized to an oligodeoxynucleotide complementary to exon sequences upstream of a given 5' splice site, and the RNA strands of the resulting RNA:DNA hybrids are cleaved by RNase H. The cleaved RNAs are then subjected to primer extension using a 32P-labelled primer complementary to exon sequences downstream of an appropriate 3' splice site. Since the primer extension products all terminate at the site of RNase H cleavage, their lengths are indicative of the splice sites utilized. The method simplifies the study of the processing of complex pre-mRNAs by allowing the splicing events between any two exons to be analyzed. We have used this approach to characterize the RNAs generated by expression of the rat tropomyosin 1 (Tm 1) gene in various rat tissues and in cultured cells after transient transfection. The results demonstrate that this method is suitable for the analysis of alternative RNA processing in vivo.     

Identification of an hnRNP A1-dependent splicing silencer in the human papillomavirus type 16 L1 coding region that prevents premature expression of the late L1 gene

We have previously identified cis-acting RNA sequences in the human papillomavirus type 16 (HPV-16) L1 coding region which inhibit expression of L1 from eukaryotic expression plasmids. Here we have determined the function of one of these RNA elements, and we provide evidence that this RNA element is a splicing silencer which suppresses the use of the 3' splice site located immediately upstream of the L1 AUG. We also show that this splice site is inefficiently utilized as a result of a suboptimal polypyrimidine tract. Introduction of point mutations in the L1 coding region that altered the RNA sequence without affecting the L1 protein sequence resulted in the inactivation of the splicing silencer and induced splicing to the L1 3' splice site. These mutations also prevented the interaction of the RNA silencer with a 35-kDa cellular protein identified here as hnRNP A1. The splicing silencer in L1 inhibits splicing in vitro, and splicing can be restored by the addition of RNAs containing an hnRNP A1 binding site to the reaction, demonstrating that hnRNP A1 inhibits splicing of the late HPV-16 mRNAs through the splicing silencer sequence. While we show that one role of the splicing silencer is to determine the ratio between partially spliced L2/L1 mRNAs and spliced L1 mRNAs, we also demonstrate that it inhibits splicing from the major 5' splice site in the early region to the L1 3' splice site, thereby playing an essential role in preventing late gene expression at an early stage of the viral life cycle. We speculate that the activity of the splicing silencer and possibly the concentration of hnRNP A1 in the HPV-16-infected cell determines the ability of the virus to establish a persistent infection which remains undetected by the host immune surveillance.     

Uncoupling two functions of the U1 small nuclear ribonucleoprotein particle during in vitro splicing.

To probe functions of the U1 small nuclear ribonucleoprotein particle (snRNP) during in vitro splicing, we have used unusual splicing substrates which replace the 5' splice site region of an adenovirus substrate with spliced leader (SL) RNA sequences from Leptomonas collosoma or Caenorhabditis elegans. In agreement with previous results (J.P. Bruzik and J.A. Steitz, Cell 62:889-899, 1990), we find that oligonucleotide-targeted RNase H destruction of the 5' end of U1 snRNA inhibits the splicing of a standard adenovirus splicing substrate but not of the SL RNA-containing substrates. However, use of an antisense 2'-O-methyl oligoribonucleotide that disrupts the first stem of U1 snRNA as well as stably sequestering positions of U1 snRNA involved in 5' and 3' splice site recognition inhibits the splicing of both the SL constructs and the standard adenovirus substrate. The 2'-O-methyl oligoribonucleotide is no more effective than RNase H pretreatment in preventing pairing of U1 with the 5' splice site, as assessed by inhibition of psoralen cross-link formation between the SL RNA-containing substrate and U1. The 2'-O-methyl oligoribonucleotide does not alter the protein composition of the U1 monoparticle or deplete the system of essential splicing factors. Native gel analysis indicates that the 2'-O-methyl oligoribonucleotide inhibits splicing by diminishing the formation of splicing complexes. One interpretation of these results is that removal of the 5' end of U1 inhibits base pairing in a different way than sequestering the same sequence with a complementary oligoribonucleotide. Alternatively, our data may indicate that two elements near the 5' end of U1 RNA normally act during spliceosome assembly; the extreme 5' end base pairs with the 5' splice site, while the sequence or structural integrity of stem I is essential for some additional function. It follows that different introns may differ in their use of the repertoire of U1 snRNP functions.     

Splicing of cauliflower mosaic virus 35S RNA is essential for viral infectivity.

A splicing event essential for the infectivity of a plant pararetrovirus has been characterized. Transient expression experiments using reporter constructs revealed a splice donor site in the leader sequence of the cauliflower mosaic virus (CaMV) 35S RNA and three additional splice donor sites within open reading frame (ORF) I. All four donors use the same splice acceptor within ORF II. Splicing between the leader and ORF II produces an mRNA from which ORF III and, in the presence of the CaMV translational transactivator, ORF IV can be translated efficiently. The other three splicing events produce RNAs encoding ORF I-II in-frame fusions. All four spliced CaMV RNAs were detected in CaMV-infected plants. Virus mutants in which the splice acceptor site in ORF II is inactivated are not infectious, indicating that splicing plays an essential role in the CaMV life cycle. The results presented here suggest a model for viral gene expression in which RNA splicing is required to provide appropriate substrate mRNAs for the specialized translation mechanisms of CaMV.     

Determination of an RNA structure involved in splicing inhibition of a muscle-specific exon

We have investigated the RNA structure of the region surrounding the muscle-specific exon 6B of the chicken beta-tropomyosin gene. We have used a variety of chemical and enzymatic probes: dimethylsulfate, N-cyclohexyl-N'-(2-(N-methylmorpholino)-ethyl)-carbodiimide-p-tolu enesulfonate) , RNase T1 and RNase V1. Lead acetate was also used to obtain some information on the tertiary structure of this region. Probing the wild-type sequence suggests a model involving one-stem and three-stem-loop structures in and around this exon. Two of these, hairpin I and stem III, have previously been implicated in repression of splicing of the intron following exon 6B in a HeLa nuclear extract. Stem I includes sequences at the beginning of exon 6B and stem III results from interaction of the intron upstream from exon 6B with sequences in the middle of the intron downstream from this exon (the intron whose splicing is repressed). Neither stem I nor stem III directly involves the consensus sequences (5' splice site, branch-point, 3' splice site) of the repressed intron. Probing RNAs that are derepressed for splicing of this intron show that there are structural changes around the 5' splice site and branch-point sequence that correlate with the derepression. This is true, despite the fact that the derepressed RNAs are altered in a region far from these consensus sequences. The most striking structural correlation with splicing capacity of the intron downstream from exon 6B is seen by probing with lead acetate. Lead ions cut RNA at specific residues; these sites are very sensitive to RNA tertiary structure. Repressed and derepressed RNAs show entirely different cleavage patterns after incubation with lead acetate. Remarkably, hybridizing a derepressed RNA with an RNA comprising the ascending arm of stem III not only re-establishes repression, but also converts the pattern of susceptibility to attack by lead ions over the whole molecule. We suggest that RNA conformation plays a role in keeping exon 6B from being spliced into non-muscle cell mRNA.     

Nuclear Pnn/DRS protein binds to spliced mRNPs and participates in mRNA processing and export via interaction with RNPS1

Pnn/DRS protein is associated with desmosomes and colocalizes with splicing factors in nuclear speckled domains. The potential interaction of Pnn with RNPS1, a pre-mRNA splicing factor and a component of the exon-exon junction complex, prompted us to examine whether Pnn is involved in nuclear mRNA processing. By immunoprecipitation, we found that Pnn associates preferentially with mRNAs produced by splicing in vitro. Oligonucleotide-directed RNase H digestion revealed that Pnn binds to the spliced mRNAs at a position immediately upstream of the splice junction and that 5' splice site utilization determines the location of Pnn in alternatively spliced mRNAs. Immunoprecipitation further showed that Pnn binds to mRNAs produced from a transiently expressed reporter in vivo. Although associated with mRNPs, Pnn is a nuclear-restricted protein as revealed by the heterokaryon assay. Overexpression of an amino-terminal fragment of Pnn that directly interacts with RNPS1 leads to blockage of pre-mRNA splicing. However, although suppression of Pnn expression shows no significant effect on splicing, it leads to some extent to nuclear accumulation of bulk poly(A)(+) RNA. Therefore, Pnn may participate, via its interaction with RNPS1, in mRNA metabolism in the nucleus, including mRNA splicing and export.